BRPI1105917B1 - REFRIGERATOR CONTAINING AN ICE MAKER, A TRAY, A DRIVE UNIT CONNECTED TO THE SAME AND A REFRIGERATION ELEMENT - Google Patents

Abstract

refrigerator including ice maker summary. a refrigerator that includes an ice maker is disclosed. the refrigerator includes an ice maker comprising: an ice maker tray swiveled in it; a drive unit connected to the ice maker selectively; and a cooling element provided in the ice tray, contactable with water supplied to the ice tray.

Description

REFRIGERATOR CONTAINING AN ICE MAKER, A TRAY, A DRIVE UNIT CONNECTED TO THE SAME AND A REFRIGERATION ELEMENT Field

The arrangements may concern a refrigerator that includes an ice maker, more particularly, a refrigerator capable of making ice more quickly, increasing the speed of cooling the water received in an ice tray.

Foundations

Generally, a refrigerator is an electrical appliance that is able to freeze or refrigerate food stored in it using a refrigerating cycle. This refrigerator includes a cabinet with a storage compartment, such as a freezer compartment or a refrigerator compartment and a door arranged in the cabinet to open and close the storage compartment.

An ice maker is provided in the storage compartment or on the door to make or maintain ice. An ice maker, including an ice maker, is provided in the ice maker. A water supply device is provided on the ice tray to supply water to the ice tray.

According to an ice-making process carried out in the conventional refrigerator, water is supplied to the ice-making tray by the water supply device. Once cold air is drawn into the ice chamber, the water received in the ice chamber is frozen and preformed ice is made.

When ice making is complete, the ice tray is rotated and twisted and the ice is separated from the ice tray. The separated ice is released and ejected into the ice storage container disposed adjacent to the ice tray.

In the case of making ice, the time to make ice is determined based on the time needed to cool the water supplied to the ice making tray (here referred to as "water").

Therefore, the need to consider the user's convenience, reducing the time to make ice, is placed.

SUMMARY

Thus, the modalities can be directed to a refrigerator, including an ice maker. To solve the problems, an objective of the modalities may be to provide an ice maker capable of making ice more quickly, increasing the cooling speed of the water received in an ice maker tray provided in it, and a refrigerator including the ice maker.

In order to achieve these objectives and other advantages and, according to the purpose of the modalities, as widely described here, a refrigerator includes an ice maker, which comprises an ice maker tray provided therein pivotally; a drive unit connected to the ice tray to selectively rotate the ice tray; and a cooling element provided on the ice tray, which can be contacted with the water supplied to the ice tray.

The ice tray can be transformable when the ice is ejected and the cooling element can be transformable, corresponding to the transformation of the ice tray.

The ice tray can be rotated and the cooling element can correspond to the rotation of the ice tray.

The cooling element can be elastically transformable.

The cooling element can be disposed in a longitudinal direction of the ice tray and the cooling element can be disposed within an ice making recess formed in the ice tray to receive water therein.

The cooling element can be mounted on the ice tray and the cooling element can be prevented from being separated from the ice tray.

The refrigerator may also include a fixing groove provided in the ice tray to securely insert a predetermined area of the cooling element in it; and a fixing piece provided in the cooling element to be inserted in the fixing groove.

A plurality of ice making recesses can be provided and the plurality of ice making recesses can be divided by a dividing wall, and the cooling element can include a plurality of cooling fins arranged in each of the contactable ice recesses. with the water received in the ice-making recesses, the plurality of cooling fins spaced from each other; and a connecting part that connects the cooling fins together.

The plurality of the cooling fins can form a plurality of spaces within the ice making recesses.

The cooling fin may be a plate fin provided in a shape corresponding to a sectional shape of the ice making recess.

The connecting part can be arranged above the partition wall, in a state of being folded.

The cooling element can be arranged in a longitudinal direction of the ice tray, along a center inside the ice tray.

The cooling element can be arranged in a longitudinal direction of the ice tray, along an inner wall inside the ice tray.

The ice tray may further include a first partition wall disposed between one end and the other end of the ice tray, through an inner center of the ice tray, along a longitudinal direction of the ice tray, and the cooling element can be arranged adjacent to at least one of the inner walls of the ice tray, in front of the first partition wall.

The cooler may further include a second partition wall that crosses connected with the first partition wall to form a plurality of ice making recesses in conjunction with the first partition wall, and the cooling element may include a plurality of cooling fins arranged in the plurality the ice-making recesses, respectively, being contactable with the water received in the ice-making recesses; and a connecting part connecting the plurality of cooling fins to each other, being arranged above the second partition wall.

In another aspect, a refrigerator includes a cabinet with a storage compartment; a door rotatably coupled to the cabinet to open and close the storage compartment; an ice maker provided at the door; an ice maker provided in the ice maker, characterized by the fact that the ice maker may include an ice maker case; an ice maker provided rotatingly in the ice maker case, being elastically transformable when the ice is ejected; a rotating element provided in the ice maker case, being connected to the ice maker to rotate the ice maker selectively; and a cooling element arranged on the ice tray, being contactable with the water supplied to the ice tray, the cooling element being elastically transformable, corresponding to the transformation of the ice tray.

In another aspect, a refrigerator includes a cabinet composed of a freezer compartment; and an ice maker provided in the freezer compartment, in which the ice maker can include an ice maker case; an ice maker provided rotatingly in the ice maker case, being elastically transformable when the ice is ejected; a drive unit provided in the ice maker case, being connected with the ice maker to rotate the ice maker selectively; and a cooling element arranged on the ice tray, being contactable with water supplied to the ice tray, the cooling element being elastically transformable, corresponding to the transformation of the ice tray.

In another aspect, a refrigerator includes a cabinet comprising a freezer compartment and a refrigerator compartment; an ice maker provided in the refrigerator compartment, divided from the refrigerator compartment, to extract cold air inside the freezer compartment through a duct; and an ice maker provided in the ice maker, wherein the ice maker may include an ice maker case; an ice maker provided rotatingly in the ice maker case, being elastically transformable when the ice is ejected; a drive unit provided in the ice maker case, being connected to the ice maker to rotate the ice maker selectively; and a cooling element arranged on the ice tray, being contactable with the water supplied to the ice tray, the cooling element being elastically transformable, corresponding to the transformation of the ice tray.

BRIEF DESCRIPTION OF THE DRAWINGS

Arrangements and arrangements can be described in detail with reference to the following drawings in which similar reference numbers refer to similar elements, and in which:
FIG. 1 is a perspective view illustrating a refrigerator including an ice maker according to an embodiment;
FIG. 2 is an enlarged perspective view illustrating the ice maker according to the embodiment;
FIG. 3 is a perspective view illustrating the ice maker connection;
FIG. 4 is an enlarged perspective view showing an ice maker and a cooling element according to an embodiment;
FIG. 5 is a perspective view showing the connection of the ice maker and the cooling element;
FIGS. 6 and 7 are perspective views illustrating an operation of ejecting the ice tray according to the mode;
FIG. 8 is an enlarged perspective view showing an ice maker and a cooling element according to another embodiment;
FIGS. 9 and 10 are perspective views illustrating an eject operation performed on the ice tray according to an embodiment shown in FIG. 8;
FIG. 11 is a perspective view illustrating a refrigerator including the ice maker arranged in a freezer compartment provided therein; and
FIG. 12 is a perspective view illustrating a refrigerator including the ice maker arranged in a refrigerator compartment provided therein.

DETAILED DESCRIPTION

Reference can now be made in detail for specific modalities, examples of which can be illustrated in the accompanying drawings. Whenever possible, the same reference numbers can be used in the drawings to refer to the same or similar parts.

As shown in FIG. 1, a refrigerator according to one embodiment includes a cabinet 1 having freezer and refrigerator compartments 2 and 3, a refrigerator compartment door 12 pivotally arranged in cabinet 1 to open and close the refrigerator compartment 2 and a freezer compartment door 13 to open and close the freezer compartment.

Here, in this mode, the refrigerator compartment 2 can be provided in an upper part of the cabinet 1 and the freezer compartment 3 can be provided in a lower part of the cabinet 1. However, the mode is not so limited. A freezer type refrigerator on top, including freezer compartment 3 arranged at the top of cabinet 1, or a side-by-side refrigerator with freezer and refrigerator compartments placed side by side can be applied to the modality.

An ice maker 20 can be provided on a rear surface of the cooler compartment door 12. An ice maker 100 for making ice and an ice storage container 200 for receiving ejected ice from ice maker 100 can be provided at ice maker 20.

Ice maker 100 can include an ice maker 110 to receive water in it and a driving unit 130 connected to ice maker 110 to rotate the ice maker 110.

A water supply hose 140 can be provided above the ice maker 110 to supply water to the ice maker 110.

A cold air inlet 211 and a cold air outlet 212 can be provided on a side surface of the ice chamber 20 to extract cold air into the ice chamber 20 and to extract cold air out of the chamber ice 20, respectively.

The cold air inlet 211 and the cold air outlet 212 can be connected with cold air guide ducts 220 arranged on a side surface of the cabinet 1, respectively.

The cold air duct 220 can be configured to move the cold air inside the freezer compartment 3 provided in a lower area of the cabinet 1 towards the ice maker 20 and to remove the cold air inside the ice maker 20 towards freezer compartment 3 simultaneously.

More specifically, since cold air is generated in an evaporator 6 supplied behind the freezer compartment 3, a large amount of cold air can be attracted to the freezer compartment 3 by driving a cold air fan 7, disposed adjacent to the evaporator. 6 and a part of the remaining cooling can be moved to the ice chamber 20 by the cold air guide duct 220.

When a user closes the door of the refrigerator compartment 12 under the frame, the cold air inlet 211 and the cold air outlet 212 can be connected with the cold air guide ducts 220, respectively.

A cold air conductor 230 can be provided in the ice chamber 20 to concentrate the cold air that passes outside the cold air inlet 211 in the ice chamber 20.

The cold air conductor 230 can be arranged to an inner wall of the ice chamber 20, where the cold air inlet 211 is formed, above the ice chamber 20, more specifically, the ice tray 110, being spaced of the ice maker tray 110.

Here, the cold air conductor 230 can be installed adjacent to the water supply hose 140.

As shown in FIG. 2, the ice maker 100 can include the ice maker 110, the drive unit 130 and even a splash-proof plate 150. The ice maker 110 can include a separate ice maker 111 in a plurality of specific spaces. The splash-proof plate 150 can be provided adjacent to the side of the ice maker 110. The drive unit 130 can be supplied next to the ice maker 110.

The drive unit 130 can include a case 131 and a rotation element 132 provided in case 131. The rotation element 132 can include a rotation motor and can be connected with the ice maker 110 to rotate the ice maker 110 .

As a result, the ice tray 110 that receives the ice can be rotated by rotating the rotation element 132. When the rotation element 132 is rotated at a predetermined angle, the ice maker 110 can be rotated and the ice received in the ice tray 110 can be detached and ejected from it.

In the meantime, a cooling element 120 can be provided on the ice maker 110, crossing the inside of the ice maker 110. Cooling element 120 can contact the water provided in the ice maker 110 to increase the water cooling speed.

Typically, the ice tray 110 can be formed of a resin material having elasticity to be rotated and twisted. However, the resin material has lower thermal conductivity than a metal material and may be limited in improving the water cooling speed.

To overcome the limitation, the cooling element 120 can be formed from a material such as metal, with greater thermal conductivity than the thermal conductivity of a material that forms the ice maker 110. The cooling element 120 formed from the material with the greatest Thermal conductivity can be arranged on the ice maker 110 to contact the water. Because of this, the cooling speed of the water can be increased and the time to make ice can be reduced.

Here, the cooling element 120 can be arranged along a longitudinal direction with respect to the ice maker 110 and can be accommodated in the ice maker 110, with a large area of it in contact with water.

In the meantime, a complete ice detection sensor 250 can be provided below the ice tray 110 to detect complete ice inside the ice storage container (200, see FIG. 1). Here, the complete ice detection sensor 250 can be a sensor that uses an infrared ray and can be a lever-type sensor.

A fixing bracket 300 can be provided on a rear surface of the ice maker 110 to fix the ice maker 100 to the ice maker 20. The supply water conductor 310 can be provided on the fixing bracket 300 to guide the water supplied to the ice maker 110.

The water supply conductor 301 can receive the water discharged from the water supply hose 140 and guide it to the ice maker 110.

The cold air conductor 230 can be supplied in a kind of adhesive form. The cold air conductor 230 may include a body 231 having an empty interior, an air inlet port 232 provided in the body 231 to communicate with the cold air inlet 211, an outlet port 233 arranged in front of the inlet port 232 and a cover member 234 arranged detachably to define an upper part of the body 231.

Here, the cover element 234 can be integrally formed with the body 231.

A predetermined sealing element can be arranged between the cold air conductor 230 and the cold air inlet 211, to prevent cold air from leaking between them.

Here, a coupling hole 236 can be provided on a side surface of the cold air conductor 230 and a coupling element 238, as a screw can be inserted into coupling hole 236 to be coupled to the mounting bracket 300. Because of this , the cold air conductor 230 can be fixedly coupled to the mounting bracket 300.

As shown in FIG. 3, a support element 135 can be provided in front of the driving unit 130 of the ice maker 100, spaced from the driving unit 130, to support the ice maker 110.

A rotation limiter (not shown) can be provided on the support elements 135. When the rotation angle of the ice maker 110 is a pre-defined angle, the rotation limiter can contact the other side of the ice tray ice maker 110 and can limit the rotation of the ice maker tray 110 as a kind of hook protrusion.

An ice maker 110a can be provided under the ice maker 110. When the ice maker 110 determines that ice making is complete, the ice maker 110 can be rotated by driving the drive unit 130.

When the ice maker 110 is rotated, both ends of the ice maker 110 can withdraw the same locus from the beginning of rotation at a predetermined angle.

Since the other end of the ice maker 110 contacts the rotation limiter (not shown) during the rotation of the ice maker 110, the rotation may no longer be performed at the other end and the ice maker 110 can stop at the point. As one end of the icing tray 110 is connected with the rotating element (132, see FIG. 2) of the driving unit 130, the end can be rotated continuously.

As mentioned above, the angle of rotation of the end is differentiated from that of the other end possessed by the ice maker 110, the ice maker 110 can be twisted and the ice accommodated in the ice maker 110 can be separated and ejected from it.

In the meantime, the cooling element 120 received in the ice maker 110 is connected with the ice maker 110. Because of this, the cooling element 120 can be rotated together with the ice maker 110 and can be twisted corresponding to the twist of the ice tray 110 thereafter.

As shown in FIG. 4, the ice maker 110 may include the plurality of ice maker recesses 111, dissociated into a plurality of columns by a partition wall 112.

The ice-making recesses 111 can be divided, with a border with the dividing wall 112. Splash-proof walls 113 and 114 can be provided apart from the outer ones arranged at both ends of the ice-making recesses 111, respectively . The splash-proof walls 113 and 114 can prevent water from splashing out when water is supplied.

In the meantime, fixation grooves 113a and 114a can be provided on the splash-proof walls 113 and 114 to insert fixation parts 123 and 124 provided at both ends of the cooling element 120 into them.

A first coupling part 115 and a second coupled part 116 can be provided at both ends of the ice maker 110, to be coupled to the rotating element (132, see FIG. 2) of the drive unit (130, see FIG. 2) and pivotally coupled to the support element (135, see FIG. 3), respectively.

The first coupling part 115 can be provided in the form of a recess to receive the rotating element 132 inserted therein. The second coupling part 116 can be provided in the form of an axis to be rotatably inserted into the support element 135.

When the rotating element 132 is rotated, the first coupling part 115 can be hollow in shape to transfer all the rotating force of the rotating element 132 to the ice maker 110 to prevent the rotating element from slipping 132.

The second coupling part 116 may be in the form of an axis, with a circular cross-sectional area, to be rotated with respect to the supporting elements 135 smoothly when the ice maker 110 is rotated.

A protrusion 117 can be arranged beside the second coupling part 116, to be contactable with the rotation limiter provided in the support element 135.

However, the cooling element 120 may include a plurality of cooling fins spaced from one another, with being formed in a shape corresponding to a lateral transverse shape of the ice making recess 111, a connector piece 122 that elastically connects two of the cooling fins. cooling 121, and fixing parts 123 and 124 fixedly inserted in the fixing grooves 113a and 114a, respectively.

This embodiment represents that the fastening parts are provided at both ends of the cooling element 120 in which they are fixedly inserted in the fastening grooves 113a and 114a. Alternatively, the fixture can be provided on only one end of the cooling element 120 and the fixation groove can be provided close to only a single side of the ice maker 110.

However, it may be considerable that the attachment part may be clip-shaped or loop-shaped, to be attached to the ice maker 110.

The cooling fins 121 can be receivable in the ice making recesses 111, respectively, and they can come in contact with the water extracted from the ice making recesses 111.

Fasteners 123 and 124 can be provided at both ends of cooling element 120. When fasteners 123 and 124 are inserted into fastening grooves 113a and 114a, the ends of fasteners 123 and 124 can be folded downwardly to avoid separating them from the fixing grooves 113a and 114a.

As a result, when the cooling element 120 is moved, the fasteners can engage with rings in the fastening grooves 113a and 114a.

The connecting pieces 122 can be bent in a "U" shape to have adequate elasticity, not arranged in a straight line, with the cooling fins 121 connected together.

When the profile of the ice maker 110 is twisted and rotated, the cooling element 120 can be twisted and rotated as well. In the event that the icing tray 110 returns to its original profile after the torsion rotation, the connection pieces 122 can provide the cooling element 120 with elastic restitution to restore the cooling element 120.

When the cooling element 120 is arranged on the ice tray 110, each of the connecting pieces 122 can be arranged above each of the partition walls 112, spaced from each of the partition walls 112.

A passage recess 112a can be provided in the partition wall 112 to allow water to travel to an area adjacent to the ice making recesses 111 when one of the ice making recesses 111 is filled with water supplied to the ice making tray 110. For do not interfere with the movement of water, the partition wall 112 can be arranged in addition to the connector piece 122.

The cooling element 120 can be arranged inside the ice tray 110 in a horizontal or longitudinal direction, and the cooling fins 121 can be accommodated in the ice making recesses 111 to divide the inside of the ice making recess 111 into a plurality of spaces.

This is because the ice that will be made in each of the ice making recesses 111 has to be of the appropriate size and the ice has to be divided. In the following, the ejection of ice according to this modality will be described in detail.

As shown in FIG. 5, cold air is supplied to the ice maker 110 and the cooling element 120. Thereafter, the cooling fins 121 can be cooled much more quickly than the ice maker 110 and a cooling fin surface temperature. 121 can be decreased below a water temperature that will be provided by this cooling.

Since water is supplied to the interior of the ice tray 110 in that state (direction "B"), the first of the ice making recesses 111, where the water is spilled, can be filled with water and the next of the ice recesses. making ice 111 may be filled with water along the guide of the recess 112a.

The water supplied to fill the ice making recesses 111 may come into contact with the surfaces of the cooling fins 121 provided in the cooling element 120 of the ice making recesses 111.

As mentioned above, the temperature of the cooling fins 121 can be much lower than that of the water supplied, and can therefore take up the heat from the water.

Heat can be removed from the water by the cold air constantly supplied to the water surface and to the surface of the ice maker 110. In addition, heat can be removed from the cooling fins 121 by them. Because of this, the cooling speed of the water can be accelerated compared to that of the water without the cooling element 120.

In particular, the ice tray 110 can be formed of resin and has a markedly deteriorated thermal conductivity compared to the cooling element 120 formed of metal. Because of this, the time to make ice with the cooling element 120 can be remarkably reduced compared to the time to make ice without the cooling element 120.

Once the ice maker 110a provided below the ice maker 110 determines whether ice making is complete, the ice maker 110 can be rotated along direction pela 'by driving the drive unit (130, see FIG 3).

FIGS. 6 and 7 are diagrams illustrating the ice maker 110 viewed in reverse from the ice maker of FIG. 5.

When the ice tray 110 can be rotated along direction "A" by the drive unit (130, see FIG. 3) as shown in FIG. 6, both ends of the ice maker 110 can be rotated by removing the same locus from the angle of rotation at a predefined angle.

In other words, until the protrusion 117 provided at the other end of the ice maker 110 comes into contact with the speed limiter 136 provided in the support element (135, see FIG. 3), the ice maker 110 can perform the rotation movement without transformation.

Since the transformation of the profile of the ice maker 110 does not occur, the ice made in the ice maker 110 can maintain the state accommodated within each of the ice maker recesses 111 formed in the ice maker 110. Obviously, the element cooling unit 120 can also be positioned on the ice maker 110 without changing the profile.

When the protrusion 117 provided at the other end of the ice maker 110 comes in contact with the speed limiter 136 to be secured as shown in FIG. 7, the rotation of the other end may not progress further.

However, as no obstacle, such as the rotation limiter 136, is provided at the end of the ice maker 110, the end of the ice maker 110 can perform the rotation movement continuously.

As a result, the angle of rotation of the ice tip that makes up the ice maker 110 may be different from the angle of rotation of the other end, such that the ice maker 110 can be twisted.

Because of the twist of the ice maker 110 mentioned above, the ice accommodated in the ice maker 110 can be separated and ejected from the ice maker recesses 111 of the ice maker 110 fall downwardly.

However, the cooling element 120 provided in the ice maker 110 can twist, corresponding to the twist of the ice maker 110.

The connection parts 122 can be folded, with cooling fins 121 elastic to each other. Because of this, an entire area of the cooling element 120 can be transformed elastically, not transformed plastically.

As a result, one (i.e. 124) of the fasteners 123 and 124 provided on the cooling element 120 which is supported by the other end of the ice maker 110 can be located in a position that corresponds to an end position of the other end of the ice maker 110. The other securing part 123 supported by the end of the ice maker 110 can be additionally rotated. Because of this, the cooling element 120 can perform the torsion.

The rotation of the end of the icing tray 110 performed by the drive unit (130, see FIG. 3) may not last permanently, but it can be stopped at a predefined angle that is greater than the rotation angle of the other end of the ice maker 110 (for example, the angle of rotation of the other end of the ice maker 110 is 150-180 degrees and the angle of rotation of the end is 200-240 degrees).

When the difference between the rotation angles of the end and the other end that make up the ice maker 110 is a predefined value, the ice ejection can be carried out smoothly and this state can be maintained for a pre-defined period of time. defined.

Once the time period has elapsed, the driving unit (130, see FIG. 3) rotates the ice maker 110 in a reverse direction of "A" and the profiles of the ice maker 110 and the cooling 120 can be returned to the originals by the elastic restoring force after the states shown in FIGS. 5 and 6.

FIG. 8 illustrates an ice maker according to another embodiment. The other elements can be the same as the elements of the above modality, except the ice maker 1110 and the cooling element 120. Because of this, a detailed description of the other elements will be made in reference to the above modality.

As shown in FIG. 8, the divided ice-making recess 1111 can be provided in the ice-making tray 1110. The ice-making recesses 1111 may include a first dividing wall 1112 arranged throughout the interior of the ice-making tray 1110 along a longitudinal direction ( horizontal direction in the drawing of FIG. 8) and a second partition wall 1122 which intersects with the first partition wall 1112, to divide the interior of the ice maker 1110 into a plurality of columns.

A passageway recess 1112a can be formed in the first partition wall 1112 to guide the filled water within one of the ice making recesses 1111 towards an area adjacent to one of the ice making recesses 1111.

Splashproof walls 1113 and 1114 can be provided close to the outer side of the ice making recesses 111 to prevent the water supplied from splashing out.

According to this modality, two cooling elements 120 can be arranged adjacent to an internal wall 1150 of the ice maker 1110, apart from each other, different from the single cooling element 120 located in the center of the ice maker according to the above mode.

As a result, the fixation grooves 1113a and 1114a can be provided in the splash-proof walls 1113 and 1114 to securely insert the fixation parts 123 and 124 provided at both ends of the cooling element 120 into them. However, the positions of the fixing grooves 1113a and 1114a may be different from those of the fixing grooves described in the above embodiment.

In other words, the two fixing slots 1113a and 1114a can be arranged on the side areas of each splash-proof wall 1113 and 1114.

A first coupling part 1115 coupled to a rotating element (132, see FIG. 2) of the drive unit (130, see FIG. 2) and a second coupling part 1116 rotatably coupled to the support element (135, see FIG. 3) can be provided at both ends of the 1110 ice tray, respectively.

The first coupling part 1115 can be in the form of a groove for inserting the respective rotating element 132. The second coupling part 1116 can be in the form of an axis to be rotatably inserted into the support element 135.

The first coupling part 1115 can be formed in a hollow form to prevent slipping, in order to transfer all the rotational force of the rotating element 132 to the ice maker 1110.

The second coupling part 1116 can be axis shaped, with a sectional area in circular shape, to be rotated relative to the support element 135 smoothly when the ice maker 1110 is rotated.

A protrusion 1117 can be arranged next to the second coupling part 1116, to be contactable with a speed limiter provided in the support element 135.

In the meantime, the cooling element 120 may include a plurality of cooling fins spaced apart from one another, being formed in a shape corresponding to a side sectional area of the ice making recess 1111, a connector piece 122 that elastically connects two of the cooling fins. cooling 121, and fixing parts 123 and 124 fixedly inserted in the fixing grooves 1113a and 114a, respectively.

The cooling fins 121 can be receivable in the ice making recesses 1111, respectively, and can come in contact with the water extracted in the ice making recesses 1111.

Fasteners 123 and 124 can be provided at both ends of cooling element 120. When fasteners 123 and 124 are inserted into fastening grooves 1113a and 1114a, the ends of fasteners 123 and 124 can be folded downwardly to avoid separating them from the fixing grooves 1113a and 1114a.

As a result, when the cooling element 120 is moved, the fasteners 123 and 124 can engage with rings in the fastening grooves 1113a and 1114a.

The connecting pieces 122 can be curved in a "U" shape to have adequate elasticity, not arranged in a straight line, connecting the cooling fins 121 to each other.

When the ice maker 1110 is twisted and rotated, the cooling element 120 can be twisted and rotated as well. In the event that the icing tray 1110 returns to its original position after rotation, the connecting pieces 122 can provide the cooling element 120 with elastic restitution to restore the cooling element 120.

When the cooling element 120 is disposed on the ice maker 1110, each of the connecting pieces 122 can be disposed above the first partition wall 1112, spaced from an upper surface of the first partition wall 1112.

Like the above embodiment, the first partition wall 1112 can be arranged separate from the connection piece 122 so as not to interfere with the movement of water between the ice making recesses 1111.

This mode also represents that the cooling element 120 can be arranged inside the ice maker 1110 in a horizontal or longitudinal direction, and that the cooling fins 121 can be accommodated in the ice maker recesses 1111. Next, the operation of the modality will be described.

As shown in FIG. 8, cold air can be provided near the ice maker 1110 and the cooling element 120. Thereafter, the cooling fins 121 can be cooled much more quickly than the ice maker 1110 and a surface temperature of the fins cooling system 121 can be decreased below a water temperature that will be provided by that cooling.

Since water is supplied to the inside of the ice maker 1110 (direction "B") in this state, the first of the ice maker 1111 recesses where the water is spilled may be filled with water. Thereafter, the next of the ice making recesses 1111 may be filled with water along the guide of the passage recess 1112a provided on the first partition wall 1112 and the passage recess 1112a provided on the second partition wall 1122.

The water from the ice-making recesses 1111 can come in contact with the surfaces of the cooling fins 121 provided in the cooling element 120 accommodated in the ice-making recess 1111.

The cooling element 120 can be provided on each of the inner walls of the ice maker 1110. As a result, the cooling speed of the water independently accommodated in each of the ice making recesses can be increased.

As mentioned above, the temperature of the cooling fin 121 can be much lower than that of the supplied water and can take up heat from the water because of this.

Heat can be removed from the water both by the cold air constantly supplied to the water surface and by the surface of the 1110 ice tray. In addition, the heat can be removed from the cooling fins 121 by them. Because of this, the cooling speed of the water can be accelerated compared to that of the water without the cooling element 120.

Even in this embodiment, the ice maker tray 1110 can be formed of resin, and has a markedly deteriorated thermal conductivity compared to the cooling element 120 formed of metal. Because of this, the time to make ice with cooling element 120 can be markedly reduced compared to the time to make ice without cooling element 120.

Once the ice maker 110a provided below the ice maker 1110 determines that ice making is complete, the ice maker 1110 can be rotated along the Ά 'direction by driving the drive unit (130, see FIG 3).

FIGS. 9 and 10 are diagrams illustrating the ice maker 1110 viewed in reverse from the ice maker of FIG. 8.

When the ice maker 1110 can be rotated along the "A" direction by the drive unit (130, see FIG. 3) as shown in FIG. 9, both ends of the ice maker 1110 can be rotated by removing the same locus from an initial rotation point at a predefined angle.

In other words, until the protrusion 1117 provided at the other end of the ice maker 1110 contacts the speed limiter 136 provided in the support element (135, see FIG. 3), the ice maker 1110 can perform the rotation movement without transformation.

Since the transformation of the ice maker 1110 profile does not occur, the ice made in the ice maker 1110 can maintain the state accommodated within each of the ice maker 1111 recesses formed in the ice maker 1110. Obviously, the element cooling unit 120 can also be positioned on the 1110 ice tray without changing the profile.

When protrusion 1117 provided at the other end of the ice maker 1110 comes into contact with the speed limiter 136 to be secured as shown in FIG. 10, the rotation of the other end may not progress further.

However, since no obstacle, such as the rotation limiter 136, is provided at the end of the ice maker 1110, the end of the ice maker 1110 can perform the rotation movement continuously.

As a result, the angle of rotation of the end that makes up the ice maker 1110 can be different from the angle of rotation of the other end, such that the ice maker 1110 can be twisted.

Because of the twisting of the ice maker 1110 mentioned above, the ice accommodated in the ice maker 1110 can be separated and ejected from the ice maker recesses 1111 of the ice maker 1110 to fall downwardly.

In the meantime, the cooling elements 120 provided adjacent the inner walls of the ice maker 1110 can perform a twist, corresponding to the twist of the ice maker 1110.

The connecting pieces 122 can be folded, connecting the cooling fins 121 to each other elastically. Because of this, an entire area of the cooling element 120 can be transformed elastically, not plastically.

As a result, one (i.e. 124) of the fasteners 123 and 124 provided on the cooling element 120 which is supported by the other end of the ice maker 1110 can be located in a position that corresponds to an end position of the other end of the ice maker 1110. The other fixing piece 123 supported by the end of the ice maker 1110 can be rotated additionally. Because of this, the cooling element 120 can perform the torsion.

The rotation of the end of the icing tray 1110 performed by the drive unit (130, see FIG. 3) may not last permanently, but it can be stopped at a predefined angle that is greater than the rotation angle of the other end of the ice maker 1110 (for example, the angle of rotation of the other end of the ice maker 1110 is 150-180 degrees and the angle of rotation of the end is 200-240 degrees).

When the difference between the rotation angles of the end and the other end that make up the 1110 ice maker tray is a predefined value, the ice ejection can be performed smoothly and this state can be maintained for a pre-defined period of time. defined.

At the end of the time, the driving unit (130, see FIG. 3) rotates the ice maker 1110 along the reverse direction of “A”.

Thereafter, the profiles of the icing tray 1110 and the cooling element 120 can be returned to the original profiles by the elastic restoring force after the states shown in FIGS. 9 and 8.

FIGS. 11 and 12 illustrate the ice maker shown in FIGS. 2 to 10 which is organized in a refrigerator with a different structure than the refrigerator structure shown in FIG. 1.

The ice maker arranged in FIGS. 11 and 12 can include the cooling element and the ice tray according to the previous embodiment, or it can include the cooling element and the ice tray according to the latter embodiment.

In FIG. 11, a cooler compartment 53 can be provided in an area to the left of cabinet 51 and a freezer compartment 52 can be provided in an area to the right of cabinet 51. Ice maker 100 and an ice storage container 1200 can be provided. supplied in an upper area of the freezer compartment.

Freezer compartment 53 can be supplied below zero degrees. Therefore, an auxiliary ice maker configured to thermally insulate the area near the ice maker 100 may not be necessary.

Here, the ice storage container 1200 can be in communication with a dispenser 64 provided in a freezer compartment door that opens and closes freezer compartment 53, and the mode may not be limited by that.

The configuration and operation of the ice maker shown in FIG. 11 can be the same as the ice maker shown in FIG. 1, and their detailed description will be omitted accordingly.

A refrigerator structure shown in FIG. 12 is the same as the structure of the refrigerator shown in FIG. 12, except that the ice maker is arranged in a cooler compartment.

As a result, an auxiliary ice maker 20 to accommodate ice maker 100 and an ice storage container 1200 can be provided in cooler compartment 2 to thermally insulate them from cooler compartment 2.

The temperature of the refrigerator compartment 2 can be above zero. If ice maker 100 and ice storage container 1200 are not separated from cooler compartment 2, ice ejection and ice storage may be impossible.

Also in the refrigerator, the configuration of the ice maker 100 accommodated in the ice maker 20 can be the same as that of the ice maker according to the modalities described with reference to FIGS. 2 to 10, and the detailed description of the ice maker configuration 100 will be omitted accordingly.

Any reference in this specification to "modality", "a modality", "exemplary modality", etc. means that a particular feature, structure, or feature described with respect to the modality is included in at least one embodiment of the invention. The appearances of phrases of this type in several parts of the specification are not necessarily all related to the same modality. In addition, when a particular function, structure or characteristic is described in relation to any modality, it is assumed that it is within the competence of a person skilled in the art to affect that function, structure or characteristic with respect to other modalities. Although modalities have been described with reference to a series of illustrative modalities of them, it should be understood that several other modifications and modalities that will be within the spirit and scope of the principles of this disclosure can be developed by those skilled in the art. More particularly, several variations and modifications are possible in the component parts and / or arrangements of the arrangement of the combination in question, within the scope of the disclosure, the drawings and the attached claims. In addition to variations and modifications in the component parts and / or arrangements, alternative uses will also be evident for those skilled in the art.

ADVANTAGEOUS TECHNICAL EFFECT

According to the modalities, the cooling element having the cooling fins with a predetermined area can be received in the ice making recesses of the ice tray. When the cooling element cooled by cold air comes into contact with water in this state, the water can be cooled quickly by exchanging heat with the cooling element.

As a result, the speed of making ice can be reduced considerably compared to the speed of making ice without the cooling element. Because of this, there may be an effect of reducing the total time to make ice.

In addition, the cooling fins of the cooling element can be elastically bonded together. Because of this, when the ice tray is rotated in a reverse state to eject the ice, the cooling fins can rotate correspondingly to the rotation of the ice tray. As a result, ejection from the ice tray may not be interfered with.

In addition, the cooling element has the elastic restoring force. When the ice tray returns, after completing the ejection, the cooling element can be replaced, not transformed plastically. Because of this, the cooling element can constantly exchange heat with water when ice is ejected, and can distribute to the accelerated speed of making ice.

It must be understood that both the preceding general description and the following detailed description of the modalities or arrangements are exemplary and explanatory and are intended to provide further explanation of the modalities as claimed.

Claims (13)

Refrigerator, characterized by the fact that it comprises an ice maker (100), comprising:
an ice maker (110) pivoted on it; a driving unit (130) connected to the ice tray to selectively rotate the ice tray; and
a cooling element (120) provided on the ice maker, contactable with water supplied to the ice maker,
wherein a plurality of the ice making recesses (111) is provided and the plurality of the ice making recesses is divided by a dividing wall in the ice making tray, and
the cooling element comprises,
a plurality of cooling fins (121) arranged in each of the ice making recesses, contactable with the water received in the ice making recesses, the plurality of cooling fins spaced apart from each other; and a connecting part (122) that connects the cooling fins together and where the cooling fin is a plate provided in a shape corresponding to a sectional shape of the ice making recess. Refrigerator, according to claim 1, characterized by the fact that the ice maker (110) is transformed when the ice is ejected; and
the cooling element (120) is transformed, corresponding to the transformation of the ice tray. Refrigerator, according to claim 2, characterized by the fact that the ice maker tray (110) is twisted round, and
the cooling element (120) corresponds to the rotation of the ice maker. Refrigerator according to claim 2, characterized by the fact that the cooling element (120) is elastically transformable. Refrigerator according to claim 2, characterized by the fact that the cooling element (120) is arranged in a longitudinal direction of the ice maker, and
the cooling element is disposed within an ice-making recess formed in the ice-making tray to receive water therein. Refrigerator according to claim 2, characterized in that the cooling element (120) is mounted on the ice maker and the cooling element is prevented from being separated from the ice maker. Refrigerator, according to claim 2, further characterized by the fact that it comprises:
a fixing groove (1113a, 1114a) provided on the ice tray to securely insert a predetermined area of the cooling element into it; and
a fixing part (124, 124) provided on the cooling element to be inserted in the fixing groove Refrigerator according to claim 1, characterized by the fact that the plurality of cooling fins (121) forms a plurality of spaces within the ice-making recesses. Refrigerator according to claim 1, characterized by the fact that the connecting part (122) is arranged above the partition wall, in a state of being folded. Refrigerator according to claim 2, characterized by the fact that the cooling element (120) is arranged in a longitudinal direction of the ice tray, along a center inside the ice tray. Refrigerator according to claim 2, characterized by the fact that the cooling element (120) is arranged in a longitudinal direction of the ice maker, along an internal wall inside the ice maker. Refrigerator according to claim 2, characterized in that the ice tray further comprises: a first partition wall (1112) disposed between one end and the other end of the ice tray, through an inner center of the tray ice maker, along a longitudinal direction of the ice maker, and the cooling element (120) is disposed adjacent to at least one of the inner walls of the ice maker, in front of the first partition wall. Refrigerator according to claim 12, further characterized by the fact that it comprises: a second partition wall (1122) which crosses connected with the first partition wall to form a plurality of ice making recesses together with the first partition wall.

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